Programación de Sistemas

Presentación del tema: "Programación de Sistemas"— Transcripción de la presentación:

1 Programación de Sistemas
JavaCC Programación de Sistemas

2 Que es un generador de parsers?
T o t a l = p r e c i + v ; Scanner Total = precio + iva ; Parser asignación Total = Expr Parser generator (JavaCC) id id precio iva Especificación lexica+gramatical

3 JavaCC JavaCC (Java Compiler Compiler) es un generador de scanner y parser Producir un scanner y/o parser escrito en java, mismo que está escrito en Java; Hay muchos generadores de parsers yacc (Yet Another Compiler-Compiler) para el lenguaje de programación C Bison de gnu.org Hay también muchos generadores de parsers escritos en Java¿ JavaCUP; ANTLR; SableCC

4 Más sobre la clasificación de generadores de parsers en java
Herramientas generadoras de Parsers ascendentes. JavaCUP; jay, YACC for Java SableCC, The Sable Compiler Compiler Herramientas generadoras de Parsers descendentes ANTLR, Another Tool for Language Recognition JavaCC, Java Compiler Compiler

5 Características de JavaCC
Generador de Parsers descendentes LL(K) Especificación Lexica y gramática en un archivo Procesador Tree Building con JJTree Extremadamente Ajustable Muchas opciones diferentes seleccionables Generación de Documentación Utilizando JJDoc Internacionalización Puede manejar unicode completo Lookahead Sintáctico y Semántico

6 Características de JavaCC (cont.)
Permite especificaciones extendidas en BNF Puede utilizar | * ? + () en RHS. Estados y acciones Lexicas. Análisis léxico sensitivo a mayúsculas y minúsculas Capacidad de depuración extensiva Tokens especiales Reporteador de error muy bueno

7 Instalación de JavaCC Descargar el archivo javacc-3.X.zip desde Seguir el enlace que dice Download o ir directamente a unzip javacc-3.X.zip en un directorio %JCC_HOME% add %JCC_HOME\bin directory to your %path%. javacc, jjtree, jjdoc may now be invoked directly from the command line.

8 Pasos para usar JavaCC Escribir una especificación JavaCC (.jj file)
Define la gramática y acciones en un archivo (digamos, calc.jj) Ejecutar javaCC para generar un scanner y un parser javacc calc.jj Generará el parser, scanner, token,… java sources Escribe el programa que utilice el parser Por ejemplo, UseParser.java Compilar y ejecutar el programa javac -classpath . *.java java -cp . mainpackage.MainClass

9 Ejemplo 1 Parsear una especificación de expresiones regulares y que coincidan con las cadenas de entrada Grammar : re.jj Ejemplo % todas las cadenas terminan en "ab" (a|b)*ab; aba; ababb; Nuestras tareas: Por cada cadena de entrada (Linea 3,4) determinar cuando coincida con la expresión regular (linea 2).

10 La película completa REParserTokenManager javaCC REParser re.jj tokens
resultado MainClass % comentario (a|b)*ab; a; ab;

11 Formato de una gramática de entrada para JavaCC
javacc_options PARSER_BEGIN ( <IDENTIFIER>1 ) unidad_de_compilación_de_java PARSER_END ( <IDENTIFIER>2 ) ( produccion )*

12 El archivo de especificación de entrada (re.jj)
options { USER_TOKEN_MANAGER=false; BUILD_TOKEN_MANAGER=true; OUTPUT_DIRECTORY="./reparser"; STATIC=false; }

13 re.jj PARSER_BEGIN(REParser) package reparser; import java.lang.*; …
import dfa.*; public class REParser { public FA tg = new FA(); // mensaje de error con la linea actual public static void msg(String s) { System.out.println("ERROR"+s); } public static void main(String args[]) throws Exception REParser reparser = new REParser(System.in); reparser.S(); PARSER_END(REParser)

14 re.jj (Definición de tokens)
<SYMBOL: ["0"-"9","a"-"z","A"-"Z"] > | <EPSILON: "epsilon" > | <LPAREN: "(“ > | <RPAREN: ")“ > | <OR: "|" > | <STAR: "*“ > | <SEMI: ";“ > } SKIP: { < ( [" ","\t","\n","\r","\f"] )+ > |< "%" ( ~ ["\n"] )* "\n" > { System.out.println(image); }

15 re.jj (producciones) void S() : { FA d1; } { d1 = R() <SEMI>
{ tg = d1; System.out.println("------NFA"); tg.print(); System.out.println("------DFA"); tg = tg.NFAtoDFA(); tg.print(); System.out.println("------Minimizar"); tg = tg.minimize(); tg.print(); System.out.println("------Renumerar"); tg=tg.renumber(); tg.print(); System.out.println("------Ejecutar"); } testCases()

16 re.jj void testCases() : {} { (testCase() )+ }
void testCase(): { String testInput ;} { testInput = symbols() <SEMI> { tg.execute( testInput) ; } } String symbols() : {Token token = null; StringBuffer result = new StringBuffer(); } { ( token = <SYMBOL> { result.append( token.image) ; } )* { return result.toString(); }

17 re.jj (expresiones regulares)
// R --> RUnit | RConcat | RChoice FA R() : {FA result ;} { result = RChoice() { return result; } } FA RUnit() : { FA result ; Token d1; } { ( <LPAREN> result = RChoice() <RPAREN> |<EPSILON> { result = tg.epsilon(); } | d1 = <SYMBOL> { result = tg.symbol( d1.image ); } ) { return result ; } }

18 re.jj FA RChoice() : { FA result, temp ;} { result = RConcat()
( <OR> temp = RConcat() { result = result.choice( temp ) ;} )* {return result ; } } FA RConcat() : { FA result, temp ;} { result = RStar() ( temp = RStar() { result = result.concat( temp ) ;} )* {return result ; } } FA RStar() : {FA result;} { result = RUnit() ( <STAR> { result = result.closure();} )* { return result; } }

19 Formato de una gramática de entrada de JavaCC
javacc_input ::= javacc_options PARSER_BEGIN ( <IDENTIFIER>1 ) unidad_de_compilacion_de_java PARSER_END ( <IDENTIFIER>2 ) ( production )* <EOF> Codigo de color: azul --- no-terminal <naranja> – un tipo de token morado lexema ( palabra reservada; I.e., consistente de la literal en sí misma) negro -- meta simbolos

20 Notas <IDENTIFIER> significa cualquier identificador de Java como var, class2, … IDENTIFIER significa solamente IDENTIFIER. <IDENTIFIER>1 debe ser igual a <IDENTIFIER>2 unidad_de_compilacio_de_java es cualquier codigo de java que como un todo puede aparecer legalmente en un archivo. Debe contener una declaración de clase principal con el mismo nombre que <IDENTIFIER>1 . Ejemplo: PARSER_BEGIN ( MiParser ) package mipackage; import miotropackage….; public class MiParser { … } class MiOtraClase { … } … PARSER_END (MiParser)

21 La entrada y salida de javacc
(MiEspecifLeng.jj ) javacc Token.java PARSER_BEGIN ( MiParser ) package mipackage; import miotropackage….; public class MiParser { … } class MiOtraClase { … } … PARSER_END (MiParser) ParserError.java MyParser.java MyParserTokenManager.java MyParserCostant.java

22 Notes: Token.java y ParseError.jar son los mismos para todas las entradas y pueden ser reutilizados. package declaration in *.jj are copied to all 3 outputs. import declarations in *.jj are copied to the parser and token manager files. parser file is assigned the file name <IDENTIFIER>1 .java The parser file has contents: …class MiParser { … //generated parser is inserted here. … } The generated token manager provides one public method: Token getNextToken() throws ParseError;

23 Especificación Léxica con JavaCC

24 javacc options javacc_options ::= [ options { ( option_binding )* } ]
option_binding es de la forma : <IDENTIFIER>3 = <java_literal> ; donde <IDENTIFIER>3 no es sensible a mayúsculas y minúsculas. Ejemplo: options { USER_TOKEN_MANAGER=true; BUILD_TOKEN_MANAGER=false; OUTPUT_DIRECTORY="./sax2jcc/personnel"; STATIC=false; }

25 More Options LOOKAHEAD CHOICE_AMBIGUITY_CHECK OTHER_AMBIGUITY_CHECK
java_integer_literal (1) CHOICE_AMBIGUITY_CHECK java_integer_literal (2) for A | B … | C OTHER_AMBIGUITY_CHECK java_integer_literal (1) for (A)*, (A)+ and (A)? STATIC (true) DEBUG_PARSER (false) DEBUG_LOOKAHEAD (false) DEBUG_TOKEN_MANAGER (false) OPTIMIZE_TOKEN_MANAGER java_boolean_literal (false) OUTPUT_DIRECTORY (current directory) ERROR_REPORTING (true)

26 More Options JAVA_UNICODE_ESCAPE (false) UNICODE_INPUT (false)
replace \u2245 to actual unicode (6 char  1 char) UNICODE_INPUT (false) input strearm is in unicode form IGNORE_CASE (false) USER_TOKEN_MANAGER (false) generate TokenManager interface for user’s own scanner USER_CHAR_STREAM (false) generate CharStream.java interface for user’s own inputStream BUILD_PARSER (true) java_boolean_literal BUILD_TOKEN_MANAGER (true) SANITY_CHECK (true) FORCE_LA_CHECK (false) COMMON_TOKEN_ACTION (false) invoke void CommonTokenAction(Token t) after every getNextToken() CACHE_TOKENS (false)

27 Ejemplo: Figura 2.2 if IF [a-z][a-z0-9]* ID [0-9]+ NUM
([0-9]+”.”[0-9]*) | ([0-9]*”.”[0-9]+) REAL (“--”[a-z]*”\n”) | (“ “|”\n” | “\t” )+ nonToken, WS error Notaciones javacc  “if” or “i” “f” or [“i”][“f”] [“a”-”z”]([“a”-”z”,”0”-”9”])* ([“0”-”9”])+ ([“0”-”9”])+ “.” ( [“0”-”9”] ) * | ([“0”-”9”])* ”.” ([“0”-”9”])+

28 Especificación JavaCC para algunos Tokens
PARSER_BEGIN(MiParser) class MiParser{} PARSER_END(MiParser) /* Para la expresión regular en la derecha, se retornará el token a la izquierda */ TOKEN : { < IF: “if” > | < #DIGIT: [“0”-”9”] > |< ID: [“a”-”z”] ( [“a”-”z”] | <DIGIT>)* > |< NUM: (<DIGIT>)+ > |< REAL: ( (<DIGIT>)+ “.” (<DIGIT>)* ) | ( <DIGIT>+ “.” (<DIGIT>)* ) > }

29 Continuación /* Las expresiones regulares aquí serán omitidas durante el análisis léxico */ SKIP : { < “ “> | <“\t”> |<“\n”> } /* como SKIP pero el texto saltado es accesible desde la acción del parser */ SPECIAL_TOKEN : { <“--” ([“a”-”z”])* (“\n” | “\r” | “\n\r” ) > } /* . Para cualquier subcadena que no coincida con la especificación léxica, javacc lanzara un error */ /* regla principal */ void start() : {} { (<IF> | <ID> |<NUM> |<REAL>)* }

30 Especificación de Gramática con JavaCC

31 La forma de una Producción
java_return_type java_identifier ( java_parameter_list ) : java_block {opciones_de_expansion } Ejemplo : void XMLDocument(Logger logger): { int msg = 0; } { <StartDoc> { print(token); } Element(logger) <EndDoc> { print(token); } | else() }

32 Ejemplo ( Gramática ) P  L S  id := id S  while id do S
S  begin L end S if id then S S  if id then S else S L S L L;S 1,7,8 : P  S (;S)*

33 JavaCC Version of Grammar 3.30
PARSER_BEGIN(MiParser) pulic class MiParser{} PARSRE_END(MiParser) SKIP : {“ “ | “\t” | “\n” } TOKEN: { <WHILE: “while”> | <BEGIN: “begin”> | <END:”end”> | <DO:”do”> | <IF:”if”> | <THEN : “then”> | <ELSE:”else”> | <SEMI: “;”> | <ASSIGN: “=“> |<#LETTER: [“a”-”z”]> | <ID: <LETTER>(<LETTER> | [“0”-”9”] )* > }

34 JavaCC Version of Grammar 3.30 (cont’d)
void Prog() : { } { StmList() <EOF> } void StmList(): { } { Stm() (“;” Stm() ) * } void Stm(): { } { <ID> “=“ <ID> | “while” <ID> “do” Stm() | <BEGIN> StmList() <END> | “if” <ID> “then” Stm() [ LOOKAHEAD(1) “else” Stm() ]

35 Tipos de producciones production ::= javacode_production
| regulr_expr_production | bnf_production | token_manager_decl Note: 1,3 se utilizan para definir gramáticas. 2 se usa para definir tokens 4 se usa para incrustar código en el token manager.

36 JAVACODE production javacode_production ::= “JAVACODE”
java-return_type iava_id “(“ java_param_list “)” java_block Note: Se utiliza para definir no-terminales para reconocer Used to define nonterminals for recognizing sth that is hard to parse using normal production.

37 Example JAVACODE JAVACODE void skip_to_matching_brace() { Token tok;
int nesting = 1; while (true) { tok = getToken(1); if (tok.kind == LBRACE) nesting++; if (tok.kind == RBRACE) { nesting--; if (nesting == 0) break; } tok = getNextToken(); } }

38 Note: Do not use nonterminal defined by JAVACODE at choice point without giving LOOKHEAD. void NT() : {} { skip_to_matching_brace() | some_other_production() } "{" skip_to_matching_brace() | "(" parameter_list() ")"

39 TOKEN_MANAGER_DECLS token_manager_decls ::=
TOKEN_MGR_DECLS : java_block The token manager declarations starts with the reserved word "TOKEN_MGR_DECLS" followed by a ":" and then a set of Java declarations and statements (the Java block). These declarations and statements are written into the generated token manager (MyParserTokenManager.java) and are accessible from within lexical actions. There can only be one token manager declaration in a JavaCC grammar file.

40 regular_expression_production
regular_expr_production ::= [ lexical_state_list ] regexpr_kind [ [ IGNORE_CASE ] ] : { regexpr_spec ( | regexpr_spec )* } regexpr_kind::= TOKEN | SPECIAL_TOKEN | SKIP | MORE TOKEN is used to define normal tokens SKIP is used to define skipped tokens (not passed to later parser) MORE is used to define semi-tokens (I.e. only part of a token). SPECIAL_TOKEN is between TOKEN and SKIP tokens in that it is passed on to the parser and accessible to the parser action but is ignored by production rules (not counted as an token). Useful for representing comments.

41 lexical_state_list lexical_state_list::=
< * > | < java_identifier ( , java_identifier )* > The lexical state list describes the set of lexical states for which the corresponding regular expression production applies. If this is written as "<*>", the regular expression production applies to all lexical states. Otherwise, it applies to all the lexical states in the identifier list within the angular brackets. if omitted, then a DEFAULT lexical state is assumed.

42 regexpr_spec regexpr_spec::=
regular_expression1 [ java_block ] [ : java_identifier ] Meaning: When a regular_expression1 is matched then if java_block exists then execute it if java_identifier appears, then transition to that lexical state.

43 regular_expression regular_expression ::= java_string_literal
| < [ [#] java_identifier : ] complex_regular_expression_choices > | <java_identifier> | <EOF> <EOF> is matched by end-of-file character only. (3) <java_identifier> is a reference to other labeled regular_expression. used in bnf_production java_string_literal is matched only by the string denoted by itself. (2) is used to defined a labled regular_expr and not visible to outside the current TOKEN section if # occurs. (1) for unnamed tokens

44 Example <DEFAULT, LEX_ST2> TOKEN IGNORE_CASE : {
< FLOATING_POINT_LITERAL: (["0"-"9"])+ "." (["0"-"9"])* (<EXPONENT>)? (["f","F","d","D"])? | "." (["0"-"9"])+ (<EXPONENT>)? (["f","F","d","D"])? | (["0"-"9"])+ <EXPONENT> (["f","F","d","D"])? | (["0"-"9"])+ (<EXPONENT>)? ["f","F","d","D"] > { // do Something } : LEX_ST1 | < #EXPONENT: ["e","E"] (["+","-"])? (["0"-"9"])+ > } Note: if # is omitted, E123 will be recognized erroneously as a token of kind EXPONENT.

45 Structure of complex_regular_expression
complex_regular_expression_choices::= complex_regular_expression (| complex_regular_expression )* complex_regular_expression ::= ( complex_regular_expression_unit )* complex_regular_expression_unit ::= java_string_literal | "<" java_identifier ">" | character_list | ( complex_regular_expression_choices ) [+|*|?] Note: unit concatenation;juxtaposition complex_regular_expression choice; |  complex_regular_expression_choice (.)[+|*|?]  unit

46 character_list character_list::=
[~] [ [ character_descriptor ( , character_descriptor )* ] ] character_descriptor::= java_string_literal [ - java_string_literal ] java_string_literal ::= // reference to java grammar “ singleCharString* “ note: java_sting_literal here is restricted to length 1. ex: ~[“a”,”b”] --- all chars but a and b. [“a”-”f”, “0”-”9”, “A”,”B”,”C”,”D”,”E”,”F”] --- hexadecimal digit. [“a”,”b”]+ is not a regular_expression_unit. Why ? should be written ( [“a”,”b”] )+ instead.

47 bnf_production bnf_production::=
java_return_type java_identifier "(" java_parameter_list ")" ":" java_block "{" expansion_choices "}“ expansion_choices::= expansion ( "|" expansion )* expansion::= ( expansion_unit )*

48 expansion_unit expansion_unit::= local_lookahead | java_block
| "(" expansion_choices ")" [ "+" | "*" | "?" ] | "[" expansion_choices "]" | [ java_assignment_lhs "=" ] regular_expression | [ java_assignment_lhs "=" ] java_identifier "(" java_expression_list ")“ Notes: 1 is for lookahead; 2 is for semantic action 4 = ( …)? 5 is for token match 6. is for match of other nonterminal

49 lookahead local_lookahead::= "LOOKAHEAD" "(" [ java_integer_literal ] [ "," ] [ expansion_choices ] [ "," ] [ "{" java_expression "}" ] ")“ Notes: 3 componets: max # lookahead + syntax + semantics examples: LOOKHEAD(3) LOOKAHEAD(5, Expr() <INT> | <REAL> , { true} ) More on LOOKAHEAD see minitutorial

50 returntype NT(parameters) throws ParseError;
JavaCC API Non-Terminals in the Input Grammar NT is a nonterminal => returntype NT(parameters) throws ParseError; is generated in the parser class API for Parser Actions Token token; variable always holds the last token and can be used in parser actions. exactly the same as the token returned by getToken(0). two other methods - getToken(int i) and getNextToken() can also be used in actions to traverse the token list.

51 Token class public int kind;
0 for <EOF> public int beginLine, beginColumn, endLine, endColumn; public String image; public Token next; public Token specialToken; public String toString() { return image; } public static final Token newToken(int ofKind)

52 Error reporting and recovery
It is not user friendly to throw an exception and exit the parsing once encountering a syntax error. two Exceptions ParseException .  can be recovered TokenMgrError  not expected to be recovered Error reporting modify ParseExcpetion.java or TokenMgrError.java generateParseException method is always invokable in parser action to report error

53 Error Recovery in JavaCC:
Shallow Error Recovery Deep Error Recovery Ex: void Stm() : {} { IfStm() | WhileStm() } if getToken(1) != “if” or “while” => shallow error

54 Shallow recovery can be recovered by additional choice:
void Stm() : {} { IfStm() | WhileStm() | error_skipto(SEMICOLON) } where JAVACODE void error_skipto(int kind) { ParseException e = generateParseException(); // generate the exception object. System.out.println(e.toString()); // print the error message Token t; do { t = getNextToken(); } while (t.kind != kind);}

55 Deep Error Recovery Same example: void Stm() : {} { IfStm() | WhileStm() } But this time the error occurs during paring inside IfStmt() or WhileStmt() instead of the lookahead entry. The approach: use java try-catch construct. void Stm() : {} { try { ( IfStm() | WhileStm() ) } catch (ParseException e) { error_skipto(SEMICOLON); } note: the new syntax for javacc bnf_production.

56 There are plenty examples on the net
More Examples There are plenty examples on the net JavaCC Grammar Repository

57 References Compilers Principles, Techniques and Tools, Aho, Sethi, and Ullman